Comparative microsporogenesis and flower development in Eucalyptus urophylla × E. grandis

Jun Yang; Jun Lan; Pengqiang Yao; Zhen Huang; Xiangyang Kang

doi:10.1007/s11676-015-0150-9

Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (2) : 257 -263. DOI: 10.1007/s11676-015-0150-9

Original Paper

Comparative microsporogenesis and flower development in Eucalyptus urophylla × E. grandis

Jun Yang ¹^,²
, Jun Lan ³
, Pengqiang Yao ¹^,²
, Zhen Huang ¹^,²
, Xiangyang Kang ¹^,²^,^e

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Abstract

Microsporogenesis and flower development in Eucalyptus urophylla × E. grandis were examined using chromosome tableting to provide a method to predict the meiotic stages in this species. Although microsporogenesis was normal, cytokinesis during meiosis of pollen mother cells occurred simultaneously, with strong asynchronism observed in the two different lengths of stamens in a flower bud. In a single flower, the developmental period of microsporogenesis in anthers on the longer stamens was always ahead of those on the shorter stamens. Flower development was also asynchronous at different locations on a branch. Flower buds on the upper side of the branch were larger in diameter than those on the lower side. In addition, a correlation was observed between microsporogenesis development and flower bud diameter growth. The pachytene stage was first observed when the diameter of the flower buds increased to 3.0 mm, and the majority of the meiotic stages were observed when bud diameters ranged from 3.5 to 5.0 mm. This study showed that the developmental stages of microsporogenesis in Eucalyptus urophylla × E. grandis could be distinguished readily, which may be applicable to future breeding studies.

Keywords

Eucalyptus urophylla × E. grandis / Microsporogenesis / Flower development

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Jun Yang, Jun Lan, Pengqiang Yao, Zhen Huang, Xiangyang Kang. Comparative microsporogenesis and flower development in Eucalyptus urophylla × E. grandis. Journal of Forestry Research, 2015, 27(2): 257-263 DOI:10.1007/s11676-015-0150-9

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Blackmore S, Wortley AH, Skvarla JJ, Rowley JR. Pollen wall development in flowering plants. New Phytol, 2007, 174: 483-498.

[2]	Brooker MIH. A new classification of the genus Eucalyptus L′Hér. (Myrtaceae). Aust Syst Bot, 2000, 13: 79-148.

[3]	Chen CB, Xu YY, Ma H, Chong K. Cell biological characterization of male meiosis and pollen development in rice. J Integr Plant Biol, 2005, 47: 734-744.

[4]	Custódio L, Carneiro MF, Romano A. Microsporogenesis and anther culture in carob tree (Ceratonia siliquua L.). Sci Hortic, 2005, 104: 65-77.

[5]	Davis GL. Floral morphology and the development of gametophytes in Eucalyptus melliodora A. Cunn. Aust J Bot, 1968, 16: 19-35.

[6]	Davis GL. Floral morphology and the development of the gametophytes in Eucalyptus stellulata Sieb. Aust J Bot, 1969, 17: 177-190.

[7]	Doughty RW. The Eucalyptus. A natural and commercial history of the gum tree. 2000, Baltimore: The Johns Hopkins Univ Press, 237.

[8]	Einspahr DW. Production and utilization of triploid hybrid aspen. Iowa State J Res, 1984, 58: 401-409.

[9]	Eldridge K, Davidson J, Harwood C, van Wyk G. Eucalypt domestication and breeding. 1993, Oxford: Oxford University Press, 288.

[10]	Griffin AR, Burgess IP, Wolf L. Patterns of natural and manipulated hybridisation in the genus Eucalyptus L′herit. -1 a review. Aust J Bot, 1988, 36: 41-66.

[11]	Han C, Xu JM, Du ZH, Li GY, Zeng BS, Wu SJ, Wang W. Polyploidy induction of clone of Eucalyptus grandis with colchicine. Afr J Biotechnol, 2011, 10(66): 14711-14717.

[12]	Janaki-Ammal EK, Khosla SN. Breaking the barrier to polyploidy in the geneus Eucalyptus. Proc Indian Acad Sci, 1969, 70: 248-249.

[13]	Kang X, Zhu Z, Lin H. Study on the effective treating period for pollen chromosome doubling of Populus tomentosa × P. bolleana. Scientia Silvae Sinicae, 1999, 35: 21-24.

[14]	Kang X, Zhu Z, Zhang Z. Suitable period of high temperature treatment for 2n pollen of Populus tomentosa × P. bolleana. J Beijing For Univ, 2000, 22: 1-4.

[15]	Koltunow AM, Truettner J, Cox KH, Wallroth M, Goldberg RB. Different temporal and spatial gene expression patterns occur during anther development. Plant Cell, 1990, 2: 1201-1224.

[16]	Ladiges PY, Udovicic F, Nelson G. Australian biogeographical connections and the phylogeny of large genera in the plant family Myrtaceae. J Biogeogr, 2003, 30: 989-998.

[17]	Lin H, Jian M, Liang LY, Pei WJ, Liu XZ, Zhang HY. Production of polyploids from cultured shoot tips of Eucalyptus globulus Labill by treatment with colchicine. Afr J Biotechnol, 2010, 9(15): 2252-2255.

[18]	Lu M, Zhang P, Kang X. Induction of 2n female gametes in Poplus adenopoda Maxim by high temperature exposure during female gametophyte development. Breed Sci, 2013, 63: 96-103.

[19]	Mao YK, Zhang PD, Shi L, Dong CB, Suo YJ, Kang XY. The optimum conditions for inducing 2n pollen chromosome doubling by high temperature in Eucommia Ulmoides. J Beijing For Univ, 2013, 35: 53-58.

[20]	McCormick S. Control of male gametophyte development. Plant Cell, 2004, 16(Suppl.): S142-S153.

[21]	Myburg AA, Potts BM, Marques CM, Kirst M, Gion JM, Grattapaglia D, Grima-Pettenatti J. Kole C. Eucalyptus. Genome mapping and molecular breeding in plants. 2007, Berlin: Springer, 115 160

[22]	Potts BM, Dungey HS. Interspecific hybridization of Eucalyptus: key issues for breeders and geneticists. New For, 2004, 27: 115-138.

[23]	Potts BM, Jackson WD. Barlow BA. Evolutionary processes in the Tasmanian high altitude eucalypts. Flora and fauna of alpine Australiasia. Ages and origins. 1986, Melbourne: CSIRO, 511 527

[24]	Potts BM, Reid JB. Hybridisation as dispersal mechanism. Evolution, 1988, 42: 1245-1255.

[25]	Pryor LD, Johnson LAS. A classification of the Eucalypts. 1971, Canberra: Australian National University Press, 102.

[26]	Scott R, Hodge R, Paul W, Draper J. The molecular biology of anther differentiation. Plant Sci, 1991, 80: 167-191.

[27]	Scott RJ, Spielman M, Dickinson HG. Stamen structure and function. Plant Cell, 2004, 16(Suppl.): S46-S60.

[28]	Teixeira JED, Bonine CAV, Dias DD, Scarpinati EA, Aguiar AM, Toledo FHRB, Tambarussi EV, Vencovsky R. Diallel crosses among elite clones of Eucalyptus grandis and Eucalyptus urophylla. Scientia Forestalis, 2013, 41: 497-505.

[29]	Wang C, Lentini Z, Tabares E, Quintero M, Ceballos H, Dedicova B, Sautter C, Olata C, Zhang P. Microsporogenesis and pollen formation in cassava. Biol Plant, 2010, 55: 469-478.

[30]	Wang J, Kang XY, Li DL, Chen HW, Zhang PD. Induction of diploid eggs with colchicine during embryo sac development in Populus. Silvae Genetica, 2010, 59: 40-48.

[31]	Wang J, Li DL, Kang XY. Induction of unreduced megaspores with high temperature during megasporogenesis in Populus. Ann For Sci, 2012, 15: 1-9.

[32]	Weisgerber H, Rau HM, Gartner EJ, Baumeister G, Kohnert H, Karner L. 25 years of forest tree breeding in Hessen. Allgemeine For, 1980, 26: 665-712.

[33]	Wyatt R. Inflorescence architecture: how flower number, arrangement, and phenology affect pollination and fruit-set. Am J Bot, 1982, 69: 585-594.

[34]	Xu FX, Chen DQ, Specht C. Comparative microsporogenesis and anther development of selected species from Magnoliaceae. Nord J Bot, 2013, 31: 291-300.